A fibrous ceramic preform includes a plurality of ceramic fibers, a first amorphous layer, and an interfacial coating layer. The interfacial coating layer includes an anisotropic region adjacent the at least one amorphous layer, and an isotropic region on a side of the anisotropic region opposite the at least one amorphous layer.

The present invention relates to carbon material having, on the base material, a coating layer that includes TaC, and a method for producing the carbon material. For example, the carbon material may include a base material and a coating layer on the surface of the base material. The coating layer may include TaC, which may have a maximum diffraction peak value on the (111) surface, where diffraction peak values may be generated by diffractions of X-rays in XRD analysis.

The present invention relates to carbon material having, on the base material, a coating layer that includes TaC, and a method for producing the carbon material. For example, the carbon material may include a base material and a coating layer on the surface of the base material. The coating layer may include TaC, which may have a maximum diffraction peak value on the (111) surface, where diffraction peak values may be generated by diffractions of X-rays in XRD analysis.

The present invention relates to carbon material having, on the base material, a coating layer that includes tantalum carbide (TaC), and a method for producing the carbon material. For example, the carbon material may include a base material and a coating layer on the surface of the base material. The coating layer may include TaC having average crystal grain size of 10-50 m.

The present invention relates to carbon material having, on the base material, a coating layer that includes tantalum carbide (TaC), and a method for producing the carbon material. For example, the carbon material may include a base material and a coating layer on the surface of the base material. The coating layer may include TaC having average crystal grain size of 10-50 m.

Provided are a SmFeN magnetic powder which is superior not only in water resistance and corrosion resistance but also in hot water resistance, and a method of preparing the powder. The present invention relates to a method of preparing a magnetic powder, comprising: plasma-treating a gas; surface-treating a SmFeN magnetic powder with the plasma-treated gas; and forming a coat layer on the surface of the surface-treated SmFeN magnetic powder.

Provided are a SmFeN magnetic powder which is superior not only in water resistance and corrosion resistance but also in hot water resistance, and a method of preparing the powder. The present invention relates to a method of preparing a magnetic powder, comprising: plasma-treating a gas; surface-treating a SmFeN magnetic powder with the plasma-treated gas; and forming a coat layer on the surface of the surface-treated SmFeN magnetic powder.

A degradable device component or tool provided with one or more target physical parameter values and shaped from a precursor composite material. The precursor composite material includes a core material in particulate form having one or more real physical parameter values exceeding the target physical parameter values; a first layer material provided on the core material and a second layer material provided on the first layer material, wherein the first layer material and the second layer material are together capable of forming a galvanic cell; and a melted outer layer material provided directly or indirectly on the second layer, the outer layer having a melting point below the melting points of the core material, the first layer material and the second layer material.

A degradable device component or tool provided with one or more target physical parameter values and shaped from a precursor composite material. The precursor composite material includes a core material in particulate form having one or more real physical parameter values exceeding the target physical parameter values; a first layer material provided on the core material and a second layer material provided on the first layer material, wherein the first layer material and the second layer material are together capable of forming a galvanic cell; and a melted outer layer material provided directly or indirectly on the second layer, the outer layer having a melting point below the melting points of the core material, the first layer material and the second layer material.

A coated component, along with methods of its formation and use, is provided. The coated component includes a substrate having a surface; a silicon-based bond coating on the surface of the substrate; and a barrier coating on the silicon-based bond coating. The silicon-based bond coating comprises amorphous silicon phase having grains of crystalline silicon (e.g., having an average size of about 0.03 m to about 3 m) distributed therein. The amorphous silicon phase may be formed of pure silicon metal, or may be formed from silicon metal with boron, oxygen, and/or nitrogen dispersed therein.